Spacer Mold and Methods Therefor

ABSTRACT

A hip spacer mold forming a spacer with a spacer stem connected to a spacer head has a stem portion for forming a spacer stem. The hip spacer mold also has a plurality of interchangeable head modules configured for alternatively forming spacer heads of a plurality of different predetermined sizes. The head modules are configured to be disposed adjacent the stem portion.

CROSS-REFERENCE TO RELATED APPLICATION

This Continuation application claims priority from U.S. non-provisionalapplication Ser. No. 12/328,062, filed Dec. 4, 2008 which claims thebenefit of U.S. Provisional Application Ser. No. 61/012,082, filed Dec.7, 2007, the contents of which are incorporated herein by reference intheir entirety for all purposes.

FIELD OF THE INVENTION

The present invention is directed to molds for forming orthopedicimplants and, more particularly, to molds for forming temporary spacerorthopedic implants.

BACKGROUND OF THE INVENTION

From time to time, orthopedic implants such as knee or hip replacementsand the tissue around the implant become infected. The infected implantis removed, and it conventionally takes 4 to 8 weeks or more toadequately treat the infection during which time the implant site iskept immobile. This may cause unused muscles to contract and shrink thespace previously occupied by the joint implant that connectedarticulating bones such as the space between the shortened end of afemur and the acetabulum on the hip bone in the case of a hipreplacement.

To prevent the shrinkage of the implant site, one treatment is toreplace the infected permanent implant with a temporary implant orspacer made of an antibiotic-filled cement. The spacer preserves thedistance between the adjoining bones so that muscle cannot overlycontract while the infection is being cleared from the implant site.Additionally, once positioned within the body, the antibiotic leachesout of the spacer to treat tissue near the spacer and prevent furtherspreading of the infection. Once the infection is cleared, the spacer isreplaced with a new permanent implant.

Some known spacers are pre-made and are provided to the physiciansperforming the surgery. This usually provides little or no opportunityfor the physicians to significantly customize or modify the spacer tomatch the size of a patient's implant site during the surgicalprocedures for implanting the spacer.

Other spacers are molded by the physicians by filling molds with curablecement during the surgical procedure. In these cases, when hard moldsare used, substantial customization is not possible when the wrong sizemold is provided. Also, relatively cumbersome, time consuming, and messyprocedures are used to fill the molds. For instance, such hard molds areusually filled by pouring the antibiotic filled cement into mold piecesand then placing the cement into all spaces in the mold by using a spoonor spatula.

Other known relatively soft silicone spacer molds are enclosed forinjecting cement into the mold from a cement gun with a nozzle. To fillall of the spaces in the enclosed mold, extra time and effort by thephysician is required to shift the nozzle of the cement gun in differentdirections within the mold. Thus, a spacer mold is desired that permitsphysicians to easily select and adjust the size of the spacer mold evenduring surgical procedures, and efficiently and cleanly fill the spacermold.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a left side perspective view of a spacer mold connected to acement gun in accordance with the present invention;

FIG. 2 is an exploded perspective view of the spacer mold of FIG. 1;

FIG. 3 is a right side elevational view of the spacer mold of FIG. 1with a right part removed and an upper cover shown in cross-sectionalview;

FIG. 4 is fragmentary perspective view of an end of a stem portion ofthe spacer mold of FIG. 1 with a head portion removed;

FIG. 5 is a fragmentary perspective view of an end of a stem portion ofthe spacer mold of FIG. 1 with a cover removed;

FIG. 6 is a fragmentary, close-up, right side perspective view of an endof the spacer mold of FIG. 1 with a right part and a screw removed;

FIG. 7 is a fragmentary, cut-away left side view of an end of the spacermold of FIG. 1 showing the retention of an adjustable part in accordancewith the present invention;

FIG. 8 is a side perspective view of an alternative reinforcing part inaccordance with the present invention;

FIG. 9 is a simplified, side cross-sectional view showing an alternativehead section for a spacer mold in accordance with the present invention;

FIG. 10 is a simplified, side cross-sectional view showing anotheralternative head section for a spacer mold in accordance with thepresent invention;

FIG. 11 is a perspective, cross-sectional view of another alternativehead section of a spacer mold in accordance with the present invention;and

FIG. 12 is a left side perspective view of a spacer formed by the spacermold of FIG. 1 in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to FIGS. 1-3, a spacer mold 10 is releasably connected to apressurized cement cartridge 12 that fits on a cement gun such as aZimmer's PowerFlo® Bone Cement Injector that uses pressurized cartridgesof cement connected to a nozzle, for example. The cement gun can ejectcement from cartridge 12 such as high-strength, high-viscosity PMMA.This includes materials such as Palacos® R+G High Viscosity Bone Cementand any other similar material (as used herein, the term ‘cement’generally refers to any curing and hardening material suitable forimplanted spacers unless noted otherwise). The cement may be loaded withan antibiotic such as Gentamicin and/or clindamycin in order to clearinfection from tissue surrounding an implanted spacer formed by spacermold 10. As shown in FIG. 12, for one embodiment, a hip spacer 200formed by spacer mold 10 has a spacer head 202 connected to, orintegrally formed with, a spacer stem 204. A bent neck 206 connects thespacer head 202 to the spacer stem 204 to match the shape of thesuperior portion of a femur. The spacer mold 10 has a stem portion 14used to form the spacer stem 204, and a head portion 16 used to form thespacer head 202.

In one form, the stem portion 14 includes corresponding left and rightstem members 18 and 20 that may be mirror images of each other or mayhave different shapes. The left and right stem members 18 and 20 areconfigured to mate and cooperatively define a main, longitudinallyextending cavity or space 22 between them to form the spacer stem 204 inthe cavity 22. The stem members 18 and 20 each have an aligningsymmetrical groove 24 (only the groove 24 on the right stem member 20 isshown in FIG. 2) to form the cavity 22. The cavity 22 also may receive areinforcing bar 26 to be embedded within the spacer 200 when it isformed, and a stem-end mold piece 28 (also referred to as a stem plug)for forming the inferior end 208 of the spacer stem 204 that is to beimplanted on a femur.

Referring to FIG. 4, a superior end portion 30 of the stem portion 14includes two corresponding, widened sections 32 and 34 of the stemmembers 18 and 20, respectively. In the illustrated form, the widenedsections 32 and 34 respectively extend radially outward from generallylongitudinally extending outer surfaces 36 and 38 of the stem members 18and 20. The superior end portion 30 generally forms a bowl shape with agenerally circular, surface or bottom 40 and a cylindrical wall 42extending longitudinally or outwardly from the bottom 40. Thebowl-shaped superior end portion 30 defines a bottom or lower portion 44of a head molding chamber 46 (shown in FIG. 3) used to mold the spacerhead 202 therein. The bottom 40 provides the bottom of the head moldingchamber 46.

Referring to FIGS. 2-3, one or more head modules are provided, but inthis example two head modules 48 and 50 are received within the superiorend portion 30 and cooperatively define an upper portion 52 of the headmolding chamber 46. A securing member 54 releasably holds the headmodules 48 and 50 adjacent the stem portion 14, and more specifically,against the bottom 44 of the head molding chamber 46. While the securingmember 54 also covers the head modules 48 and 50, it will be understoodthat this is not necessary in all cases as long as the securing member54 keeps the head modules 48 and 50 adjacent to the stem portion 14 orin generally fixed relation to the stem portion 14 while receivingpressurized cement during filling of the spacer mold 10 and setting ofthe cement within the head molding chamber 46.

To properly match the actual size of a hip joint implant site, the stemportion 14 may be provided in different sizes. In one form, a pluralityof stem portions 14 are available where each stem portion has adifferent predetermined inner diameter for the cavity 22, such as 12 mm,14 mm, 16 mm, or 18 mm to name just a few examples, to mold spacers withthose dimensions. In this case, the inner diameter may be a generallyuniform diameter D1 (shown on FIG. 3) of a lower or inferior section 56of the stem portion 14. Alternatively, a diameter may be measured at amaximum or minimum location on the stem portion 14 especially when thecavity 22 generally tapers inward or outward.

It will be understood that other dimensions may be varied on the stemportion 14 such as additionally or alternatively providing differentaxial lengths or a variation in any other dimension for the internalcavity 22 that would be convenient to have available in different sizes.A stem portion 14 with a desired size may be ordered from themanufacturer after the implant site is conveniently measured withX-rays, imaging, or other non-evasive scanning technology. Otherwise, inone example, a plurality of the stem portions 14 may be provided in akit so that the surgeon can use the closest fitting stem portion duringa surgical procedure when the implant site is open and accessible formeasurement.

To add even further adaptability, the head modules 48 and 50 also areprovided in different predetermined sizes and are interchangeable on thestem portion 14. In the illustrated form, head modules 48 and 50 eachhave a concave, arcuate, internal surface 57 (shown in FIGS. 3) and 58(shown in FIG. 2), respectively, that are contiguous with each other tocooperatively form a generally continuous molding surface to form theupper portion 52 of the head molding chamber 46. The surfaces 57 and 58mold at least a portion of a rounded or spherical outer surface 210 ofthe spacer head 202. In one form, the surfaces 57 and 58 extend on thehead modules 48 and 50 to provide the outer surface 210 of the spacerhead with a shape that is generally about ¾ of a sphere or otherwisematches an articular surface of a femur head. The surfaces 57 and 58respectively terminate at lower, arcuate surfaces, or ends 60 and 62(also shown in FIG. 11) of the head modules 48 and 50 and are configuredto seat on the bottom 44 of the head molding chamber 46.

The internal surfaces 57 and 58 have a matching internal diameter D2(shown on FIG. 2). Thus, it will be understood that only one head modulemay be needed for a spacer mold 10 instead of two matching head modules,or more than two head modules may be used on a single spacer mold. Nomatter the number of head modules, a set of head modules may be providedwhere each head module (or each pair (or other number) of matching headmodules) alternatively provide a different inner diameter D2. In oneexample form, a set of pairs of head modules may provide inner diametersD2 of approximately 50 mm, 53 mm, 56 mm, 59 mm, 62 mm, or 65 mm. Whensuch a set is provided during a surgical procedure, the surgeon maymeasure the diameter of the acetabulum, or the remaining void on the hipwhen an implanted acetabular cup is removed from the hip to clear theinfection, and then find the head module or modules with the closestmatching inner diameter D2.

In one embodiment, while the inner diameter D2 may vary from head moduleto head module (or from pair to pair of head modules), the head moduleswill all have the same or similar exterior dimensions so that they allfit on any size stem portion 14 to provide maximum adaptability. Ofcourse, other configurations are contemplated where only certain headmodule sizes can be used with stem portions of a certain size.

Referring to FIGS. 3 and 6-7, the stem portion 14 also provides thecavity 22 with an adjustable length. Generally, the stem portion 14 hasa first member, such as the stem-end mold piece 28, and a second member,such as the stem portion 14, where the first and second members aremovable relative to each other to adjust the length of the stem moldcavity. To this end, the stem-end mold piece 28 is received, at least inpart, into the stem member or members 18 and 20 and is adjustable to aplurality of positions. Each position forms a different length for thestem mold cavity 22 to mold a spacer stem 204 of a different length.

More specifically, the stem-end mold piece 28 has a cup-shaped portion66 with an opening 68 that faces toward a section of the cavity 22 fromwhich cement will be flowing to the stem-end mold piece. In this case,the opening 68 faces an intermediate section 69 (shown in FIG. 3) of thecavity 22. The cup-shaped portion 66 is used to form the inferior end208 of the spacer stem 204. An elongated handle portion 70 on thestem-end mold piece 28 extends from the cup portion 66 andlongitudinally out of the stem portion 14 through a distal opening 72cooperatively formed by the aligned stem members 18 and 20. With thehandle portion 70 accessible, the stem portion 14 can be preassembledwith the stem-end mold piece 78 already disposed with the stem portion14 and a user can still manipulate the handle portion 70 to translatethe stem-end mold piece 28 to a desired predetermined position withinthe cavity 22.

Referring to FIG. 6, the stem-end mold piece 28 is secured in one of thepredetermined positions by a retaining mechanism 74, such as a pin 76with a grasping ring 78 at one end. The handle portion 70 of thestem-end mold piece 28 has a hole or retaining surface 80 for releasablyreceiving the pin 76. To receive and hold the pin 76 on the stem portion14, the stem members 18 and 20 each have a transversely extending,symmetrical groove 82 that align with each other to form a transversepassage or slot 84 with an opening 86 (shown best in FIG. 7) to receivethe pin 76 and an enclosed bottom 88 opposite the opening 86. While theslot 84 is generally rectangular in cross-section, it may alternativelybe a circular bore, or any other shape as long as the pin 76 is able totranslate within and be secured within the slot.

The pin 76 has a connection portion 90 for releasably connecting the pin76 to the stem portion 14. In one form, the connection portion 90 hastwo or more flexible fingers 92 with barbed ends 94. The fingers 92 arebiased outward so that they can be flexed inward to move the pin 76through the slot 84 and opening 80 on the handle portion 70. The slot 84has a widened section 96 to provide clearance for the fingers 92 toshift back outward to their natural position once the pin 76 extendsthrough the handle portion 70. In this position, the barbed ends 94oppose tapered retaining surfaces 98 at the widened section 96 thatretain the barbed ends 94 and in turn the pin 76 in the slot 84. Thisstructure limits unintentional pull-out of the pin 76 from the slot 84unless a user pulls on the grasping ring 78 with sufficient force. Thiscams the barbed ends 94 on the retaining surfaces 98 therebytransversely pressing the fingers 92 together to clear the retainingsurfaces 98 and squeeze the pin 76 so that the pin 76 can be translatedwithin the slot. The bottom 88 of the slot 84 limits further insertionof the pin 76 into the slot 84 as does a flange 100 on the pin 76 thathas a width greater than the inner width of the slot 84.

As shown in FIG. 7, for another predetermined position for the stem-endmold piece 28 relative to the stem portion 14, the pin 76 is removedfrom slot 84 and the handle portion 70. In this case, a retainingmechanism 64 includes an outwardly, radially extending flange 102 of thehandle portion 70 that engages an inner wall 104 integrally formed onthe stem portion 14 that defines opening 72. The inner wall 104 securesthe stem-end mold piece 28 on the stem portion 14. To retain thestem-end mold piece 28, the flange 102 has an outer dimension or widthgreater than an inner dimension or width of the opening 72. With the pin76 removed, either a user can pull the stem-end mold piece 28 by thehandle portion 70 and until the flange 102 engages the inner wall 104,or the pressure from cement filling the cavity 22 will push the stem-endpiece 28 outward to engage the flange 102 to the inner wall 104. Thehandle portion 70 also has a distal flange 103 with an outer dimensiongreater than the inner dimension of the opening 72 on the inner wall 104so that the distal flange 104 engages the inner wall 104 to restrictfurther translation of the stem-end mold piece 28 into the stem portion14.

With the illustrated embodiment, the stem-end mold piece 28 is providedwith at least two predetermined positions, one with the pin 76 engagedto the stem-end mold piece 28 (FIG. 6) and one without the pin 76 (FIG.7). These two positions, in one form, provide for a change in the lengthof the cavity 22 and, in turn a resulting spacer stem length, ofapproximately 40 mm from a length of approximately 160 mm to about 200mm. It will be appreciated as mentioned above, however, that the handleportion 70 may have multiple holes for receiving the pin 76 where eachhole defines a different longitudinal position for the stem-end moldpiece 28 to provide for more than two different spacer stem lengths. Itwill also be appreciated that other similar securing devices could beused instead of a pin such as, for example, locking tab and grooveconnections between stem-end mold piece 28 and stem members 18 and 20,an interference fit between the two, or even threaded connectionsbetween stem-end mold piece 28 and stem members 18 and 20 and/or betweenstem-end mold piece 28 and pin 76.

With four different stem portion sizes, six different head module sizes,and two different stem length sizes, at least 48 different spacer moldsizes are provided. It will be understood that depending on the sizesoffered and modifications of the structure as mentioned above, more orless spacer mold sizes may be provided. Thus, while in one embodimentall three of (1) the modularity of the head modules, (2) the modularityof the stem portion, and (3) the adjustability of the stem length areprovided, it will be understood that only one or two of any of thesefeatures may be provided instead.

Referring to FIGS. 1-4, the intermediate section 69 of the stem portion14 also has a port 106 that provides access to the interior or cavity 22of the stem portion 14 to receive cement injected from the cement gunand cartridge 12 or other injector of pressurized, curable material. Thecement is provided from the cartridge 12 at a pressure sufficient tospread the cement to substantially fill the spacer mold 10.Specifically, the cement fills the lower end portion 56 of the stemportion 14, filling the cup-shaped portion 66 of the stem-end mold piece28 and shifting the mold piece 28 outward if the pin 76 is not present.The cement also fills an upper portion 108 of the stem portion 14forming the neck 206 of the spacer 200, and then fills the head moldingchamber 46 within the head modules 48 and 50.

The port 106 is sufficiently rigid to remain connected to the cement gunwhile the cement is injected under relatively high pressure, such as, inone form, at approximately 300 psi to 350 psi. The remainder of thespacer mold 10 including the port 106 also has a sufficient rigidity toreceive the cement under high pressure without compromising aneffectiveness of the spacer mold and unintentional disconnect of aninjector from the port 106. In other words, the port 106 and the rest ofthe spacer mold 10 will not break, split, or crack when the pressurizedcement impacts the spacer mold 10. For these purposes, in one form, highdensity polyethylene is used to make the spacer mold 10.

The port 106 is also configured to permit the cement gun 12 to bedetached from the port 106 after filling is complete. Thus, the port 106may include an internally threaded, rigid, cylindrical wall 110 thatreleasably receives the threaded nozzle 113 of the cartridge 12. In theillustrated example, the cylindrical wall 110 has a central axis C thatextends transversely from a longitudinal axis L of the stem portion 14.

Referring to FIGS. 2-3, a detachable, externally threaded plug 112 maybe provided for closing the port 106 once the cartridge 12 is removed sothat the mold 10 can be set down in any orientation while the materialis curing in the interior cavity. The plug 112 may include at least oneend surface 114 configured for both substantially blocking the port 106and for forming a surface of a prosthesis or spacer body formed in theinterior cavity 22. The plug 112 also may be generally cylindrical andhave a cross brace or plate 116 to strengthen the plug.

Optionally, the stem portion 14 may have a second (or more) port 106 awith its own plug 112 a (shown in dashed line) spaced from port 106along the stem portion 14 to provide the cement more directly to otherparts of the cavity 22. This may better ensure the cement fills allparts of cavity 22. Also, since the cement has such a high viscosity, itis difficult for practitioners to comprehend that the cement gun createssufficient pressure to place the cement throughout the spacer mold 10.Thus, a practitioner can use the open additional port 106 a to determineby sight, if the cavity 22 is full, and then, if needed, provide extracement to further fill other areas of cavity 22 around the additionalport 106 a such as by the lower end portion 56 of the stem portion 14 inthe illustrated example.

The reinforcing bar 26 may be used to strengthen the spacer 200 andreduce the amount of cement material necessary to fill the spacer mold10. To embed the reinforcing bar 76 in the spacer 200, the reinforcingbar 26 may be generally spaced from an interior surface 122 defining thecavity 22 so that cement can generally spread to all areas between thestem portion 14 and reinforcing bar 26. For this purpose, centeringprojections 124 extend outwardly from an outer surface 120 of thereinforcing bar 26 to engage the interior surface 122. Alternatively,the centering projections 124 are separate from the reinforcing bar 26and extend from the stem portion 14 to hold the reinforcing bar 26 inthe spaced position. At least one centering projection 126 extends fromthe reinforcing bar 26 and engages at least one corresponding,interiorly extending protrusion 128 extending from the interior surface122 (or vice-versa) so that the reinforcing bar 26 is both centered awayfrom interior surface 122 and is secured longitudinally, laterally,and/or rotationally relative to the stem portion 14. In oneconfiguration, the protrusion 128 is generally ring shaped and receivesthe centering projection 126 in the protrusion's center. Here, twoprotrusion-projection engagements exist on opposite sides of thereinforcing bar 26. The reinforcing bar 26 is made of cast Co—Cr and hasa generally widened disc-shaped, head portion 130 for extending into,and filling a portion of, the head molding chamber 46 as shown in FIG.4.

Alternatively, as shown in FIG. 8, an optional reinforcing bar 132 maybe made of a generally flat piece of laser cut stainless steel. In thisform, holes 134 are cut in the reinforcing bar 132 so that cement canextend through the holes 134. Once cured, the cement is interlocked withthe reinforcing bar 132. These holes 134 can also be provided onreinforcing bar 26.

Referring again to FIGS. 1-2, the spacer mold stem members 18 and 20 arenot permanently sealed so that pressure on the members 18 and 20 canopen a thin space 152 between them to form vents 140 that permit gas orair to exhaust from the spacer mold 10 as the spacer mold is beingfilled with cement. The vents 140 also may provide a visual indicationthat the spacer mold is filled with cement when cement flows out of thevents 140. To provide the vents 140, the stem member 18 has front andback longitudinally extending flanges 142 and 144 that respectivelyoppose and align with front and back flanges 146 and 148 on the rightstem member 20. So configured, the front flanges 142 and 146 and theback flanges 144 and 148 are held together by fasteners 150 (only one isshown in FIG. 2) that can clamp the left and right stem members 18 and20 together. Space 152 (also shown on FIG. 5) exists between thecorresponding front or back flanges to form the vents 140 between atleast two fasteners 150 but may be between all fasteners or generallythroughout the entire surface area of flanges 142, 144, 146, and 148.This space 152 may exist due to manufacturing tolerances. It will beappreciated, however, that the vents 140 could be alternatively oradditionally formed by grooves or other openings on the flanges 142,144, 146 and/or 148 or by openings anywhere else on the stem portion 14or by intentionally tightening the fasteners 150 to a predeterminedless-than-maximum amount of tension.

In the illustrated embodiment, the spacer mold 10 is provided to thephysicians with the flanges 142 and 144, 146 and 148, pre-assembled toeach other with the proper amount of tension to provide the vents 140(and with the reinforcing bar 26 and stem-end mold piece 28 placedtherein). Also in the illustrated form, flanges 142 and 144 on the leftstem member 18 have an array of spaced fastener receiving collars 154that extend transversely to the longitudinal axis L and align withcollars 156 on the opposite corresponding flanges (144 and 148). Thecollars 154 and 156 receive and hold the fasteners 150. In theillustrated form, the spacer mold 10 has 15 fasteners 150 spread alongthe length of the spacer mold, although more or less could be used.

Referring to FIGS. 2-3 and 5, on the head portion 16, the securingmember 54 has a cover portion 158 and an externally threaded cylindricalportion 160 that releasably engages the threaded cylindrical wall 42 onthe upper portion 30 of the stem portion 14. So configured, the securingmember 54 can be unscrewed from the upper portion 30 to release the headmodules 48 and 50 from a cured spacer 200 formed therein. An annularstrengthening flange 159 extends outward from a joint 161 of the coverportion 158 and cylindrical portion 160. The cover portion 158 andcylindrical portion 160 cooperatively define an interior 162 thatreceives the one or more head modules 48 and 50. The securing member 54has a generally central opening or vent 164 on the cover portion 158.

The head modules 48 and 50 have opposing surfaces 166 (only one is shownin FIGS. 2-3) with pegs 168 on one head module 48 that fit in holes 170on the other head module 50 and vice-versa. The securing member 54 holdsthe opposing surfaces 166 against each other and maintains the pegs 168in the holes 170. As shown in FIG. 11, the inner diameter of thesecuring member 54, however, is slightly larger than the widest externaldimension of the head modules 48 and 50 so that a slight opening orspace 172 exists (shown in FIGS. 5 and 11) between the two head modules48 and 50. In one form, the space 172 is about 8/1000 inches wide. Thespace 172 may communicate with the vent 164 to permit gas from the headmolding chamber 46 and interiorly of the head modules 48 and 50 toescape the spacer mold 10. In the illustrated form, the head modules 48and 50 extend through the vent 164, and in turn, define the space 172 toextend through vent 164 so that gas from between the head modules 48 and50 may be released. The head modules 48 and 50 may also have snap-fitbarbs 176 to engage an upper wall 178 of the cover portion 158 to securethe head modules 48 and 50 to the securing member 54. An extension 174on the head modules 48 and 50 extends upward into the vent 164. Theextension 174 is used as leverage by pressing the extension 174 to holdthe head portions 48 and 50 in place while gripping and rotating thesecuring member 54 to detach the securing member 54 from the stemportion 14 and the head portions 48 and 50. This will overcome thesnap-fit and any adhesion between the cover portion 158 and headportions 48 and 50 caused by cement. The securing member 54 may alsohave handles 180 extending upwardly on the cover portion 158 tofacilitate the rotation.

Still referring to FIG. 11, the cover portion 158 also has two opposingprotrusions 182 that project interiorly into the interior 162 of thesecuring member 54. The protrusions 182 engage grooves 184 (shown beston FIG. 5) on an array of bracing flanges 186 that form the exterior ofthe head modules 48 and 50. With the protrusions 182 seated within thegrooves 184 on the bracing flanges 186, the head modules 48 and 50 willrotate with the securing member 54 when the securing member 54 is beingremoved from the stem portion after curing the spacer 200. Thisfacilitates breaking bonds between the dried cement of the head portion202 of the spacer 200 and the interior arcuate surfaces 57 and 58 of thehead modules 48 and 50. Once the securing member 54 is removed, the headmodules 48 and 50 can be peeled or otherwise pulled off of the headportion 202.

Referring to FIG. 9, in one alternative head portion 300, a porous core302 made of polyethylene is provided within the interior space 304formed by at least one head module or cover 306. A cavity 312 is definedbetween the core 302 and the head module 306 to receive cement. The headmodule 306 defines a centrally located vent passage 308 to release gasfrom within the interior space 304. A porous extension 310 on the core302 abuts the cover 306 adjacent the vent passage 308 and a network ofpores 314 on the core 302 provides air passage from the cavity 312 tothe vent passage 308. With this configuration, cement fills cavity 312,and then fills pores 314 and the extension 310 of the core 304. Thisdirects air from the interior spacer 304 within the cover 306 into thepores 314, and out of extension 310 and, in turn, through the ventpassage 308. An outer surface 316 of the core 302 provides a relativelylarge surface area to receive and remove gas from within the interiorspace 304. The core 302 may replace a reinforcing bar head or thereinforcing bar head may be embedded within the core 302.

Referring to FIG. 10, in another alternative head portion 400, headmodules 402 and 404 have generally the same basic shape as head modules48 and 50 but are made of a porous material as with core 302. The headmodules 402 and 404 will provide a relatively large surface area forreceiving and disposing of gas from within an interior space 406. Areinforcing head 410 may or may not be disposed within cavity 408 asdesired. Cement filling the interior space 408 will force gas from theinterior space 408, and into pores or a network of pores 412 on theinterior surface 406. The pores 412 provide passages to an extension 414on the head modules 402 and 404. The extensions 414 extend out of a ventpassage 416 defined by a cover 418 to exhaust the gas. The cover 418secures the head modules 402 and 404 to stem portion 14.

Referring again to FIG. 11, in yet another alternative head portionarrangement 500, a solid core 502 of steel, Co—Cr, or hard polymers maybe provided rather than a porous core. In this case, however, the solidcore 502 has an inner space 504 to receive reinforcing bar head 130 ofreinforcing bar 26. The core 502 and at least one head module 504cooperatively define a molding cavity 506 therebetween that has avarying thickness in order to control the flow of the cement. Morespecifically, the molding cavity 506 progresses from a maximum thicknessT1 proximal to the stem portion 14 to a minimal thickness T2 distal tothe stem portion 14 and adjacent the vent 172 on or between the headmodule 48 and 50. This is accomplished by opposing a tapered outersurface 510 of the core 502 with the spherical surfaces 57 and 58 of thehead modules 48 and 50. It will be understood that surfaces 57 and 58could by alternatively or additionally tapered instead. Otherwise, thehead portion 500 has securing member 54 and head modules 48 and 50 aswith head portion 16. The core 502 may also have an upper spacingprojection 508 that extends outward from outer surface 510 and engagessurfaces 57 and 58 to maintain the interior space 506. The projection508 has a curved, spherical-like surface 512 to engage the surfaces 57and 58 so as not to substantially block vent 172.

It will also be understood that venting of gases may take place at otherlocations as well, such as between the plug and port 106 (while thecement is setting), between the lower wall 104 of the stem portion 14and the stem-end mold piece flanges 102 or 103, between the pin 76 andthe slot 84, and between the cylindrical wall 42 of the stem portion 14and the wall 160 of the securing member 54, for example.

Referring again to FIG. 3, as another optional feature of the spacermold 10, a compliance element 188 (shown in dashed line) may be disposedwithin the cavity 22 and between the reinforcing bar 126 and theinterior surface 122 of the stem portion 14 so that the complianceelement 188 is at least partially embedded within the spacer 200. Thecompliance element 188 compresses when the curing material is placed inthe interior cavity 22 and on the compliance element 188. This resultsin the compliance element 188 applying a force to urge the cementagainst the interior surface 122 of the stem portion 14. This alsorestricts or reduces the amount of trapped gas within the cement. Thecompliance element 188 may be a balloon or other enclosed mechanicaldevice with a spring, or other device that applies an outwardly directedforce from within the spacer 200.

While in one form, the spacer mold 10 is completely assembled before thegun cartridge 12 is used to inject cement into the spacer mold 10. In analternative form, cement is placed within sections of the spacer mold 10before the spacer mold 10 is fully assembled. In this example, securingmember 54 is placed upside-down and the head modules 48 and 50 areplaced in the securing member 54. The head modules 48 and 50 are thenfilled with cement before attaching the head modules 48 and 50 andsecuring member 54 to the stem portion 14.

Similarly, the stem portion 14 may be at least partially filled withcement before the head portion 16 is attached to the stem portion 14.The stem portion 14 may be filled either through the port 106 or throughan opening 198 (shown in FIG. 4) on the upper end portion 30 of the stemportion 14. The opening 198 provides passage from the head moldingchamber 46 to the cavity 22 in the stem portion 14.

In one case, after both the head and stem portions 14 and 16 areseparately filled with cement, the head portion 16 is connected to thestem portion 14 for integrally forming the spacer head 202 with spacerstem 204. Optionally, a cement gun may be connected to the port 106 tofurther fill the spacer mold 10 with cement after the stem portion 14and the head portion 16 are connected together. This may collapse airpockets existing in the cement. In such a case, the cement may or maynot be injected under relatively high pressure.

Referring again to FIGS. 1-2, in order to remove the cured spacer 200from the spacer mold 10, the securing member 54 is unscrewed from thestem portion 14 and the head modules can be pulled away from the spacer200. The spacer mold 10 also has at least one generally longitudinallyextending, removable section 190 on one or both of the stem members 18and 20. In the illustrated form, the removable section 190 is disposedbetween two thinned strips 192 where the removable section 190 and thethinned strips 192 are integrally formed with a body or remainder 194 ofthe material forming the stem members 18 and 20. Thus, the thinnedstrips 192 connect the removable section 190 to the body 194 of thespacer mold 10. The thinned strips 192 have a sufficient thickness towithstand the lateral impact forces of the pressurized cement fromwithin the spacer mold 10 but are sufficiently thin to tear when pulledlongitudinally. One or more of the removable sections 190 may have atleast one grasping portion, such as a generally annular ring 196,connected to the at least one removable section 190 so that the graspingportion 196 can be held and pulled to remove the removable section 190from the body 194. Grasping portion 196 can be pulled by hand but alsomay be removed by tool such as by a roll-up bar placed through a ringand then rolled to roll up the removable sections 190 on the bar. In oneexample, the grasping portion 196 is integrally formed with theremovable section 190. Once the removable section 190 is removed fromthe body 194 and the spacer 200, the rest of the spacer mold body 194can be removed from the spacer 200 with tools to press, pull, or peelthe mold body 194 away from the spacer 200 or to break the body 194 intosmaller removable pieces.

While this invention has been described as having preferred embodiments,the present invention can be further modified within the spirit andscope of this disclosure. This application is therefore intended tocover any variations, uses, or adaptations of the invention using itsgeneral principles. Further, this application is intended to cover suchdepartures from the present disclosure as come within known or customarypractice in the art to which this invention pertains and which fallwithin the limits of the appended claims.

1. A hip spacer mold for forming a spacer with a spacer stem connectedto a spacer head, the hip spacer mold comprising: a stem portiondefining a stem mold cavity and having a first member and a secondmember being movable relative to each other to adjust the length of thestem mold cavity while the hip spacer mold is fully assembled.
 2. Thehip spacer mold of claim 1 wherein the first member is received at leastin part into the second member and is adjustable to a plurality ofpositions, wherein each position forms a different length for the stemmold cavity for forming a spacer stem of a different length.
 3. The hipspacer mold of claim 1 wherein the first member is controllable from anexterior of the hip spacer mold to selectively position the first memberwithin the second member while the hip spacer mold is fully assembled.4. The hip spacer mold of claim 1 further comprising a retainingmechanism configured to releasably lock the first member in a selectedposition relative to the second member.
 5. The hip spacer mold of claim4 wherein at least a portion of the retaining mechanism is integrallyformed with the first member.
 6. The hip spacer mold of claim 4 whereinthe retaining mechanism is a pin, and wherein the first member definesat least one surface for engaging the pin.
 7. The hip spacer mold ofclaim 1 wherein the second member has an interior for forming the spacerand a longitudinal end, and the first member extends within the secondmember and out of the longitudinal end.
 8. A mold for forming atemporary prosthesis comprising: a body defining an interior cavity forforming a temporary prosthesis and a port for accessing the interior,wherein the body has at least one removable section and at least onegrasping portion connected to the at least one removable section forpulling the at least one grasping portion to tear the at least oneremovable section from the body.
 9. The mold of claim 8 furthercomprising the port and the body being sufficiently rigid for releasableconnection to an injector of pressurized, curable material, in at leastat approximately 300 psi without compromising an effectiveness of themold and unintentional disconnect of an injector from the port.
 10. Themold of claim 9 wherein the port and the body are sufficiently rigid toreceive the material up to approximately at most 350 psi.
 11. The moldof claim 8 further comprising a plug for closing the port so that themold can be set in any orientation while the material is curing in theinterior cavity.
 12. The mold of claim 8 wherein the at least onegrasping portion is integrally formed with the removable section. 13.The mold of claim 8 wherein the grasping portion is generally annular.14. The mold of claim 8 wherein the body further comprises an interiorsurface with at least one interiorly extending projection for supportinga reinforcing member generally spaced from the interior surface and foraxially and rotationally fixing the reinforcing member relative to theinterior surface.
 15. A mold for forming a temporary prosthesiscomprising: a body defining an interior cavity for forming a temporaryprosthesis; a port for accessing the interior; and a plug for closingthe port, wherein the plug includes at least one surface configured forforming a surface of a prosthesis being formed in the interior cavity.16. A mold for forming a temporary prosthesis comprising: a bodydefining an interior cavity for forming a prosthesis and a port foraccess to the interior cavity for receiving pressurized curing material;and a compliance element being disposed within the interior cavity to beat least partially embedded within a prosthesis and being configured tocompress caused by curing material being placed in the interior cavityand on the compliance element so that the compliance element applies aforce to urge the curing material against the body while curing.
 17. Themold of claim 15 wherein the compliance element includes at least one ofa balloon and a spring.